Arthroscopic devices and methods

What is claimed is: 1. A resecting probe, comprising: an outer sleeve with an open distal end and an axial bore that extends proximally from the open distal end through the outer sleeve, the outer sleeve including an outer cutting window in a side of the outer sleeve proximate the open distal end of the outer sleeve; and an inner sleeve rotatably received in the axial bore of the outer sleeve so that the inner sleeve can achieve at least a first rotational position and a second rotational position in the outer sleeve, the inner sleeve including an axial extraction channel that extends through the inner sleeve for connecting to a negative pressure source; a rotatable drive coupling fixed to a proximal portion of the inner sleeve and couplable to a motor shaft for rotating the inner sleeve in the outer sleeve; a ceramic cutting member disposed at a distal end of the inner sleeve for rotation with the inner sleeve, the ceramic cutting member including at least a first burr cutting edge formed therein, the ceramic cutting member also including an inner cutting window formed therein in a first side of the ceramic cutting member, wherein the ceramic cutting member being disposed at the distal end of the inner sleeve includes the inner cutting window communicating with the axial extraction channel in the inner sleeve; and an electrode carried on the ceramic cutting member on a second side of the ceramic cutting member opposite the first side, wherein, with the inner sleeve rotatably received in the axial bore of the outer sleeve and with the ceramic cutting member disposed at the distal end of the inner sleeve, part of the ceramic cutting member extends through the open distal end of the outer sleeve to position a proximal end of the first burr cutting edge and a proximal end of the electrode distally of the open distal end of the outer sleeve, wherein, in the first rotational position, the inner cutting window aligns sufficiently with the outer cutting window to allow fluid outflow to pass through the outer cutting window and into the axial extraction channel through the inner cutting window, and wherein, in the second rotational position, the electrode aligns with a longitudinal centerline of the outer cutting window. 2. The resecting probe of claim 1 , wherein the ceramic cutting member includes at least a second burr cutting edge formed therein. 3. The resecting probe of claim 2 , wherein the electrode is disposed circumferentially between the first burr cutting edge and the second burr cutting edge on the ceramic cutting member. 4. The resecting probe of claim 1 , wherein a gap of less than 0.005 inches is maintained between the proximal end of the first burr cutting edge and the open distal end of the outer sleeve. 5. The resecting probe of claim 1 , wherein a single opening in the outer sleeve provides the outer cutting window and the open distal end. 6. The resecting probe of claim 1 , wherein a distal end of the inner cutting window is positioned proximally of the open distal end of the outer sleeve. 7. The resecting probe of claim 1 , wherein a distal end of the inner cutting window is located proximally of the proximal end of the first burr cutting edge. 8. The resecting probe of claim 1 , wherein the ceramic cutting member includes at least a first open slot formed therein in the second side of the ceramic cutting member proximal of the electrode. 9. The resecting probe of claim 1 , wherein the inner sleeve includes an aspiration aperture therein that is adjacent the electrode. 10. The resecting probe of claim 1 in combination with a handpiece coupled to the resecting probe, the handpiece including a motor drive coupled to the rotatable drive coupling. 11. The resecting probe of claim 10 in combination with a controller coupled to the handpiece for controlling rotation of the motor drive and thereby controlling rotation of the inner sleeve in the outer sleeve. 12. The resecting probe of claim 11 in combination of a negative pressure source connected to the axial extraction channel. 13. The resecting probe of claim 12 , wherein the outer sleeve further includes at least one flow aperture in a side wall of the outer sleeve and spaced apart from the outer cutting window. 14. The resecting probe of claim 13 , wherein the at least one flow aperture comprises at least one elongated slot. 15. The resecting probe of claim 13 , wherein the negative pressure source is controllable by the controller to draw fluid outflow through the at least one flow aperture and into the axial extraction channel in the inner sleeve when the inner sleeve is in the second rotational position. 16. The resecting probe of claim 15 , wherein the negative pressure source is configured to draw fluid outflow through the at least one flow aperture at a rate of at least 25 ml/min. 17. The resecting probe of claim 15 , wherein, in the first rotational position, the at least one flow aperture in the wall of the outer sleeve is blocked by a wall of the inner sleeve to inhibit passage of fluid outflow through the at least one flow aperture, and wherein, in the second rotational position, the at least one flow aperture in the wall of the outer sleeve is no longer blocked by the wall of the inner sleeve so that fluid outflow can pass through the at least one flow aperture and into the axial extraction channel in the inner sleeve. 18. The resecting probe of claim 17 , wherein the inner sleeve includes an aspiration aperture therein that is adjacent the electrode. 19. The resecting probe of claim 18 , wherein the aspiration aperture is open to the axial extraction channel so that, when the inner sleeve is in the second rotational position, the negative pressure source can simultaneously draw fluid outflow into the axial extraction channel through the aspiration aperture in the inner sleeve and through the at least one flow aperture in the outer sleeve. 20. The resecting probe of claim 19 , wherein, when the inner sleeve is in the second rotational position, the negative pressure source is able to simultaneously draw fluid outflow through the aspiration aperture in the inner sleeve at a rate of between 10 ml/min and 50 ml/min and through the at least one flow aperture in the outer sleeve at a rate of at least 50 ml/min.